DE10297119B4 - Condenser, evaporator and cooler - Google Patents

Abstract

A condenser (10) condensing a gaseous refrigerant by rejecting heat of the gaseous refrigerant to a predetermined column-like heat absorbing member (19) of an external refrigerator, comprising:
a condensing part (11);
an inlet part (12); and
an outlet part (13);
said condensing member (11) is formed of a flat plate (11) shaped to surround the entire periphery of said columnar heat-absorbing member (19),
said condensing part (11) further comprises a plurality of through bores (11a) formed along its circumferential direction and arranged parallel to each other,
said inlet (12) and outlet (13) parts are hollow tubes and each have a closed (12a, 13a) and an open end (12b, 13b),
said inlet part (12) is connected to an end face (11b) of said condensing part (11) which is perpendicular to the circumferential direction of said condensing part (11),
said inlet part is (12) with all the said continuous ...

Description

Background of the invention

The The present invention relates to a cooling device, more specifically on a capacitor that absorbs the heat a coolant to the heat rejects the absorbent part of an external chiller and liquefies it Evaporator, the heat from one to be cooled Object absorbs and the coolant evaporated and a cooling device, which includes the condenser and the evaporator.

description of the prior art

various Types of cooling devices are used to spaces or cool objects. As However, in some applications it may be difficult to absorb the heat Part of the cooling devices near from such spaces or To install objects. With a fridge in a car is used, there is difficulty, the heat-absorbing part directly because of the available Space is limited inside the car. In addition, the heating of the Interior of the car by radiating heat through the cooler be avoided. When cooling the CPU of a computer that has many interconnected parts in tight spaces are arranged, the installation of the cooling device is near the CPU even more difficult.

In order to eliminate such difficulties in installing cooling devices, a refrigeration apparatus having the configuration described below has been disclosed 10 shown is proposed. An external chiller is removed from the object to be cooled 92 placed and a coolant circulates between the heat-absorbing part 91 the external cooling machine and the object to be cooled 92 , This means that the coolant is in the heat-repellent part 51 that attaches to the heat-absorbing part 91 the external chiller is attached, cooled and then through a passage 55 in a heat-absorbing part 52 in contact with the object to be cooled 92 is provided, wherein the object 92 is cooled. The coolant attached to the heat-absorbing part 52 is heated back to the heat-repellent part 51 through a passage 56 circulated.

In the above-described refrigerator, the heat-repellent part is 51 with the heat absorbing part 91 the external refrigerating machine in a configuration thermally coupled, wherein a coolant tube to the heat-absorbing member 91 the external cooling machine is wound or laid. The heat absorbing part 52 is with the object 92 thermally coupled in the same configuration.

In the above-described refrigerator, by nature, either the heat transfer performance between the heat-absorbing member must 91 the external cooling machine and the heat-rejecting part 51 or between the object to be cooled 92 and the heat-absorbing part 52 be increased to improve their cooling efficiency.

Furthermore, the reduction of the size of the cooling apparatus is needed. In the application of the cooling apparatus for a computer CPU or the like, in which the external cooling machine is small because the object to be cooled 92 is very small and only a little heat is generated, must be the heat-absorbing part 91 attached heat-repellent part 51 and the heat-absorbing part 52 , the object 92 is attached, be small. In summary, the size reduction is either from the heat-repellent part 51 or the heat-absorbing part 52 as well as increasing their heat transfer performance important.

The chiller also requires simple and easy means to heat rejecting part 51 on the heat absorbing part 91 to attach or detach the external chiller and the heat-absorbing part 52 on the object to be cooled 92 attach or remove it without sacrificing its heat transfer performance.

The US 5,038,854 describes a heat exchanger that can be bent from a substantially planar shape into a cylinder-like shape. Within the planar structure parallel tubes are arranged, which are designed for heat exchange. Hook-like bends are provided on the ends of the heat exchanger that are perpendicular to the tubes and that can be hooked into one another to secure the heat exchanger.

The JP 611 90 289 discloses a tank heat exchanger which consists of a flexible mat with longitudinal transitions formed therein, designed to pass a heat transfer medium. With eyelets attached at the ends and complementary screws and nuts, the heat exchanger can be securely mounted around a tank. The US 5,966,957 shows a metal heat exchanger having a plurality of parallel bores in a substantially cuboidal body, wherein a coolant is passed through these holes.

Consequently, it is an object of the present the invention to provide a compact condenser and evaporator with efficient heat transfer performance and easy maintenance and to create a cooling device that includes the compact condenser and evaporator.

Summary of the invention

According to one first aspect of the present invention comprises a capacitor, the one gaseous coolant by rejecting the heat of the gas in a predetermined column-like shaped heat absorbing Part of an external cooling device condenses, a condensing part, an inlet part and a Outlet part on. The condensation part is thus made of a flat Plate shaped so that it absorbs the entire edge of the column-like shaped heat absorbing Part surrounds. The condensing part further has a plurality of through holes formed along its circumferential direction are and are arranged parallel to each other. The inlet and outlet part, the hollow tubes are, have a closed or an open end. The inlet part is with one end side of the condensing part, which is perpendicular to the circumferential direction of the condensing part, connected. The inlet part has a connection with all the through holes. The outlet part is connected to the other end side of the condensing part, which is perpendicular to the circumferential direction of the condensing part, connected. The outlet part has a connection with all the through holes. The open end of the inlet part is with an influence passage of the coolant connected. The open end of the outlet part is with a discharge passage the coolant, whose sectional area is smaller is connected as the influence passage. The condensation part is in the columnar shape Heat-absorbing part added and fixed in it.

Under End sides of the condensing part perpendicular to its circumference not only those who stand by sharing his be formed in two semicircles, but also those by cutting the condensing part formed part of its scope, understood.

By doing one uses the configuration described above, provides the present Invention the functions and effects mentioned below. If namely the temperature of a coolant only on the heat Reducing part is reduced, not more than the amount Heat rejected, with the multiplier of the heat capacity of the coolant corresponds to the temperature difference of the coolant. on the other hand allows the present invention to reject a larger amount of heat, by a coolant vapor is condensed on the condensing part to a highly effective heat transfer to reach. Furthermore the condensing part is configured so that the entire edge of the columnar shaped heat-absorbing parts surrounded by a flat plate, with a certain number is present at tight through holes. Consequently, the Heat absorption part and the heat-condensing part attached to it be smaller while the heat transfer area can be bigger.

Of Furthermore, the attachment and removal can be easier because of Condensing part only by inserting into the columnar attached heat-absorbing part attached will be improved, and the mounting and the feasibility of maintenance will be improved, without losing its heat transfer performance affect.

The section the discharge passage of the coolant is less than that of the Influence passage, because of a smaller cut surface for the drainage passage is sufficient, since the volume of the refrigerant vapor drastically decreases when condensing.

According to one second aspect of the present invention, the capacitor is made the first aspect of the invention additionally equipped with a clamp, which is shaped so that it encloses the condensation part, which in the columnar shaped Heat-absorbing part added is and by closing the clamp is attached to it.

At the Applying the configuration described above provides the invention the features and effects described below. If, if the Condensation part in the columnar shaped heat Absorption part inserted is, either the outer edge of heat absorbent part or the inner circumference of the condensing part not precise are made, touch they relax, which causes worse heat transfer performance. As always, in the present invention, in which the outer circumference of the condensing member to the heat-absorbing member by a Clamp is attached, touch These are tight, allowing for easy attachment and removal without the Heat transfer performance to impair allows. Consequently, the invention improves the possibilities of assembly, maintenance and inspection, without the heat transfer efficiency to impair.

According to one third aspect of the present invention includes either the Condensing part of the first aspect or of the second Aspect a variety of hollow tubes that are parallel to each other are arranged.

In this configuration can almost the same functions and effects as the ones mentioned above a lower price can be achieved.

According to one fourth aspect of the present invention comprises an evaporator, the one liquid coolant evaporates by heat from an external heat source absorbed, an evaporation part, an inlet part and a Outlet part on. The evaporation part is made of a flat plate, those with a variety of through holes that face each other are arranged in parallel, equipped, shaped. The inlet part and the outlet part, the hollow tubes are, have a closed or an open end. The inlet part is connected to an end portion of the evaporation part on its outer circumferential surface. The inlet part is further connected to all the through holes. The outlet part is at the other end of the evaporation part connected at its outer peripheral surface. The outlet part is further connected to all the through holes. The open end of the inlet part is with a coolant influencing passage connected. The open end of the outlet part is with a coolant outflow passage connected, the sectional area is greater than the influence passage. The evaporation part is to the external heat source appropriate.

The mentioned above Configuration of the present invention provides the following mentioned effects. In general, when raising the temperature of a cold, liquid refrigerant on a cooling part no less than the amount of heat absorbed by the Multiplier of the heat capacity of the liquid coolant corresponds to the temperature difference of the coolant. On the other hand can in the present invention, when the liquid refrigerant is at an evaporator is evaporated, a lot of heat, that of its heat of vaporization corresponds to be absorbed, achieving a higher heat transfer performance becomes. Furthermore, the size of the evaporator, the to the external heat source is attached, because the heat transfer area of the evaporator through the use of a flat plate through which a number of made through continuous, mutually parallel holes was, is bigger. This configuration of the present invention is for highly integrated, small objects like CPUs for Computer especially effective.

Of Further, the evaporator using screw nuts or Simply clamp on to be cooled Objects attached or objects to be cooled be removed, the assembly, the maintenance and the inspection of the Evaporator can be improved without losing its heat transfer performance to impair.

Of Further, in the evaporator of the present invention, the section the coolant outflow passage greater than the influence passage, since the volume of the refrigerant during evaporation very strongly increases.

According to one fifth Aspect of the present invention comprises an evaporator, a liquid coolant evaporates by heat absorbed from the passing air, an evaporation part, a Einlassteil, an outlet part and a cooling fin on. The evaporation part is formed from a flat plate that comes with a variety of through holes, which are arranged parallel to each other, Is provided. The evaporation part is bent to a room include, a predetermined amount and length Has.

The cooling fin is inserted in the room, which crosses the direction of the through holes. The inlet part and the outlet part, which are hollow tubes, have a closed or an open end. The inlet part is connected to the one lower end portion of the evaporation part at its outer circumferential surface. The inlet part is further connected to all the through holes. The outlet part is with the other, higher end of the evaporation part connected at its outer peripheral surface. The outlet part is furthermore with all the through holes connected. The open end of the inlet part is with a coolant influencing passage connected. The open end of the outlet part is with a coolant outflow passage connected, their sectional area is larger than the influence passage.

The mentioned above Configuration of the present invention provides the following mentioned effects. The heat transfer area the evaporator can be enlarged by making a flat plate with a number of through holes is used. Furthermore, the evaporator with a long length of be small in size, if you bend it. And further know the heat transfer area, through the warm air is flowing, to be enlarged by putting the cooling fin between the curved evaporation part Installed. Consequently, the evaporator can be of small size, while the heat transfer area, through which the warm air and the coolant flow are increased can.

According to one Sixth aspect of the present invention is the evaporation part either from their fourth or fifth aspect of a variety of hollow tubes, which are arranged parallel to each other, shaped.

By using the above-mentioned configuration of the present invention, the same effects as previously mentioned can be lowered Costs are achieved.

According to one Seventh aspect of the present invention is a cooling device to disposal put the capacitor from the first, second or third Aspect of the invention and the evaporator of the fourth, fifth or sixth aspect of the invention, wherein the outflow passage of Condenser is connected to the influence passage of the evaporator and the influence passage of the condenser with the outflow passage the evaporator is connected.

The mentioned above Configuration of the present invention can reduce the size of the device the cooling efficiency increase and the feasibility Improve assembly, maintenance and inspection.

Short description the drawings

1 is a schematic side view of the capacitor according to the present invention.

2 is a schematic front view of the capacitor according to the present invention.

3 is a schematic enlarged view of the cooling device according to the present invention.

4 Fig. 12 is a schematic enlarged perspective view of the inlet and outlet parts of the cooling device according to the present invention.

5 is a schematic plan view of the evaporator according to the present invention.

6 is a schematic front view of the evaporator according to the present invention.

7 Figure 11 is a schematic perspective view of the evaporator with the thin cooling fin between the curved evaporation part.

8th Fig. 12 is a schematic arrangement view of hollow tubes used for the condenser or the evaporator according to the present invention.

9 is a schematic view of a refrigerant drive pump according to the present invention.

10 is a schematic view of a conventional cooling apparatus.

Detailed description the preferred embodiments

1 and 2 show a capacitor 10 condensing a vaporized refrigerant by transferring heat to a cylindrical heat absorption part 19 rejects having an external cooling device. The capacitor 10 has a condensation part 11 , an inlet part 12 , an outlet part 13 and a clamp 14 on. As the refrigerant, a material is selected which is suitable for phase changes from the gaseous to the liquid state, for example something like carbon dioxide. Depending on the temperature of the heat-absorbing part 19 and the like, an appropriate refrigerant pressure and a suitable filling pressure are selected. The condensation part 11 includes a flat aluminum plate that is shaped to be the outer edge of the cylindrical heat-absorbing member 19 surrounds.

As in 3 shown is the flat plate 11 so provided that a number of through holes 11a in the direction of the circumference of the condensing part 11 is arranged parallel to each other. The flat plate 11 is divided into two semicircles at two points in its circumference; the end surfaces 11b and 11c perpendicular to the circumference of the flat plate 11 stand. While the inlet part 12 so with the end face 11b the flat plate 11 connected is that he with all the through holes 11a is connected, is the outlet part 13 so with the end face 11c the flat plate 11 connected that he with all the through holes 11a connected is.

As in 4 shown are the inlet part 12 and the outlet part 13 made of hollow aluminum tubes, the closed ends 12a . 13a and open ends 12b . 13b to have. The slots 12c . 13c are on the peripheral surface of the inlet part 12 or the outlet part 13 shaped and with the end faces 11b . 11c the flat plate 11 connected by soldering or brazing. While the open end 12b of the inlet part 12 by brazing or brazing with a coolant inflow passage 15 , which is made of aluminum tubes connected, is the open end 13b of the outlet part 13 by soldering with a coolant outflow passage 16 connected. The cross-sectional area of the discharge passage 16 is smaller than the influence passage 15 ,

the clamp 14 includes an isolation 14c and a band 14a , The isolation 14c is made of polycarbonate thermoplastic resin semicircular shaped to be the outer edge of the condensing part 11 surrounds. The ribbon 14a is made of stainless steel cylindrically shaped so that it is the outer surface of the insulation 14c surrounds. The condensation part 11 is in the cylindrical heat absorpti onsteil 19 inserted and fixed in such a way that the tape 14a by inserting bolts 17 in through holes, at both end parts 14b of the band 14a are formed, and bolting the bolts 17 with nutmegs 18 , is attached.

The isolation 14c Synthetic resin is used as it allows to prevent heat from the air from the environment to the condensing part 11 and also makes it possible to use the elasticity of the synthetic resin to uniform radial pressure for fixing the band 14a applied.

In another embodiment, the condensation part 11 formed with a peripheral shape and cut in one place thereon to form two end surfaces, and then each of the two end surfaces is with the inlet part 12 or with the outlet part 13 connected.

5 and 6 show an evaporator 20 , the one vicious part 21 , an inlet part 22 and an outlet part 23 Contains and vaporizes the coolant by removing heat from an external heat source 29 is absorbed. The evaporation part 21 includes a flat aluminum plate with a number of through holes 21a which are arranged parallel to each other. The inlet part 22 and the outlet part 23 are formed from hollow aluminum tubes and have closed ends 22a . 23a or open ends 22b . 23b , An end part 21b of the evaporation part 21 is with the outer surface of the inlet part 22 connected by soldering so that all through holes 21 associated with it. The other end part 21c of the evaporation part 21 is so with the outer surface of the Auslassteiles 23 connected by soldering that all the through holes 21a associated with it.

The open end 22b of the inlet part 22 is with the coolant influencing passage 25 connected by soldering and the open end 23b of the outlet part 23 is with the coolant outflow passage 26 connected by soldering. The cross-sectional area of the discharge passage 26 is larger than the influence passage 25 , The evaporation part 21 is in a head block 24 Made of aluminum, inserted and attached to the top of the external heat source 29 at its through holes 24a screwed.

The evaporation part 21 and the head block 24 can be integrally formed as an integral part and, for example, by means of a cover instead of the head block 24 directly to the top of the external heat source 29 be attached.

7 shows an evaporator 30 which vaporizes a liquid refrigerant by absorbing heat from a continuous air. The evaporator 30 includes an evaporation part 31 , an inlet part 32 , an outlet part 33 and cooling fins 34 , The evaporation part 31 is made of a flat aluminum plate with a variety of through holes 31a , which are arranged parallel to each other, shaped. And the evaporation part 31 is curved in three places and forms between its straight places three rooms, which have a rectangular cross-section. The cooling fins 34 are wavy shaped with thin aluminum plate and at the top of the waveform in the spaces adjacent to the flat surfaces of the evaporation part 31 adjoin, inserted.

The inlet part 32 and the outlet part 33 are hollow aluminum tubes that have a closed end 32a . 33a or an open end 32b . 33b to have.

The inlet part 32 is with a lower end part of the evaporation part 31 connected at its outer peripheral surface. The inlet part 32 is also with all the through holes 31a connected.

The outlet part 33 is with the other higher end of the evaporation part 31 connected at its outer peripheral surface. The outlet part 33 is also with all the through holes 31a connected.

Then the open end 32b of the inlet part 32 with a coolant influencing passage 35 , which was made of an aluminum tube connected. And the open end 33b of the outlet part 33 is with a coolant outflow passage 36 connected, which was made of an aluminum tube whose sectional area is greater than that of the influence passage 35 ,

Using the configuration described above, the liquefied coolant flows through the influential passage 35 in the lower part of the evaporation part 31 , then gradually evaporates within the through holes 31a and finally flows from the higher part of the evaporation part 31 through the discharge passage 36 with a larger cut surface.

In the above invention, the number of curvature areas of the evaporation part is 31 not limited to three, also one, two, four or more areas of curvature are possible. Also the waveform of the cooling fin 34 does not have to be U-shaped, but can also be V- or different.

8th shows a variety of hollow tubes 41 , which are arranged and fixed parallel to each other by soldering. Each of the hollow tubes 41 is out Aluminum and has 1 mm diameter. If you have those hollow tubes 41 used, either the condensing part 11 or the evaporation part 21 . 31 be made in a simpler way and at a lower price.

By putting the capacitor 10 and the evaporator 20 of the present invention in the heat-repellent part 51 or the heat-absorption part 52 in 10 employs a compact cooling device, which has a higher cooling efficiency and easy maintenance is achieved.

When the capacitor 10 , as in 10 shown is positioned at a location that is higher than the one at which the evaporator 20 is positioned, the coolant can continuously circulate without an external energy due to the difference in gravity between the liquid and the vaporized coolant. However, if the capacitor 10 at approximately the same location or lower location than the evaporator 20 is positioned, the coolant can not circulate without a drive pump.

9 shows a drive pump 60 , which is called "Fish Tail Pump" and is known for its compact and simple structure. The drive pump 60 is in a coolant passage 65 installed and with a leaf spring 61 at a base 63 fitted. As a small part of a metal like iron on the leaf spring 61 attached, it is powered by an electromagnet 64 made to swing. The vibration of the leaf spring 61 emits the coolant in such a way that the "fish" moves its "caudal fin". A small amount of energy is enough to send out the coolant if the leaf spring 61 is vibrated at its resonant speed.

Claims (7)

A capacitor, 10 ) condensing a gaseous refrigerant by transferring heat of the gaseous refrigerant to a predetermined column-like heat absorption part ( 19 ) an external cooling device, comprising: a condensation part ( 11 ); an inlet part ( 12 ); and an outlet part ( 13 ); said condensation part ( 11 ) is from a flat plate ( 11 ) formed so as to cover the entire edge of said columnar heat-absorbing member (10) 19 ), said condensing part ( 11 ) further includes a plurality of through holes ( 11a ) formed along its circumferential direction and arranged parallel to each other, said inlet ( 12 ) and said outlet part ( 13 ) are hollow tubes and each have a closed ( 12a . 13a ) and an open end ( 12b . 13b ), said inlet part ( 12 ) has one end face ( 11b ) of said condensing part ( 11 ) perpendicular to the circumferential direction of said condensing part ( 11 ), said inlet part is ( 12 ) with all said through holes ( 11a ), said outlet part ( 13 ) is with the other end side ( 11c ) of said condensing part ( 11 ) perpendicular to the circumferential direction of the condensing part ( 11 ), said outlet part ( 13 ) is with all the said through holes ( 11a ), said open end ( 12b ) of said inlet part ( 12 ) is with an influence passage ( 15 ) for the coolant, said open end ( 13b ) of the outlet part ( 13 ) is connected to a discharge passage for the coolant, whose cross-sectional area is smaller than that of the said influence passage ( 15 ), said condensing part ( 11 ) is in the columnar-shaped heat absorption part ( 19 ) and fixed therein. Capacitor ( 10 ) according to claim 1, provided with a clamp ( 14 ) shaped to receive said condensing part ( 11 ) and inserted into the columnar heat-absorption member ( 19 ) and fixed by the closing of said clamp ( 14 ). Capacitor ( 10 ) according to claim 1 or 2, wherein said condensing part ( 11 ) a plurality of hollow tubes ( 11a ), which are arranged parallel to each other, contains. Evaporator ( 20 ) which vaporizes a liquid coolant by dissipating heat from an external heat source ( 29 ), comprising: an evaporation part ( 21 ); an inlet part ( 22 ); and an outlet part ( 23 ); said evaporation part ( 21 ) is with a flat plate ( 21 ) formed with a plurality of through holes ( 21a ), which are arranged parallel to one another, said inlet ( 22 ) and said outlet part ( 23 ) are hollow tubes and each have a closed ( 22a . 23a ) and an open end ( 22b . 23b ), said inlet part ( 22 ) has an end region ( 21b ) of said evaporation part ( 21 ) connected to its outer circumferential surface, said inlet part ( 22 ) is further provided with all said through holes ( 21a ), said outlet part ( 23 ) is with the other end region ( 21c ) of said evaporation part ( 21 ) connected to its outer circumferential surface, said outlet part ( 23 ) is further provided with all said through holes ( 21a ) connected, said open end ( 22b ) of said inlet part ( 22 ) is with an influence passage ( 25 ) for said coolant, said open end ( 23b ) of said outlet part ( 23 ) is with a discharge passage ( 26 ) for the said coolant whose sectional area is greater than that of said influence passage ( 25 ), said evaporation part ( 21 ) is connected to the said external heat source ( 29 ) appropriate. Evaporator ( 30 ) which vaporizes a liquid refrigerant by absorbing heat from a continuous air, comprising: an evaporation part ( 31 ); an inlet part ( 32 ); and an outlet part ( 33 ); a cooling fin ( 34 ); said evaporation part ( 31 ) is from a flat plate ( 31 ) formed with a plurality of through holes ( 31a ), which are arranged parallel to each other, is equipped, said evaporation part ( 31 ) is curved to form a space therebetween having a predetermined height and length, said cooling fin ( 34 ) is inserted in said space, the said direction of the through holes ( 31a ) cuts, said inlet ( 32 ) and said outlet part ( 33 ) are hollow tubes, each one a closed ( 32a . 33a ) and an open end ( 32b . 33b ), said inlet part ( 32 ) is with a lower end portion of said evaporation part ( 31 ) connected to its outer circumferential surface, said inlet part ( 32 ) is further provided with all said through holes ( 31a ), said outlet part ( 33 ) is connected to the other higher end region of said evaporation part ( 31 ) connected to its outer circumferential surface, said outlet part ( 33 ) is further provided with all said through holes ( 31a ), said open end ( 32b ) of said inlet part ( 32 ) is with an influence passage ( 35 ) of said coolant, said open end ( 33b ) of said outlet part ( 33 ) is with a discharge passage ( 36 ) of said coolant whose cross-sectional area is greater than that of said influence passage ( 35 ), connected. Evaporator ( 20 . 30 ) according to claims 4 and 5, wherein said evaporation part ( 21 . 31 ) of a plurality of hollow tubes ( 21a . 31a ), which are arranged parallel to each other, is formed. Cooling device, comprising: a capacitor ( 10 ) mentioned in claim 1, 2 or 3; an evaporator ( 20 . 30 ) mentioned in claim 4, 5 or 6; wherein an outflow passage ( 13 ) of said capacitor ( 10 ) with an influence passage ( 22 . 32 ) of said evaporator ( 20 . 30 ) and an influence passage ( 12 ) of said capacitor ( 10 ) with a discharge passage ( 23 . 33 ) of said evaporator ( 20 . 30 ) connected is.